4nu3 Citations

Structure-based characterization and antifreeze properties of a hyperactive ice-binding protein from the Antarctic bacterium Flavobacterium frigoris PS1.

Do H, Kim SJ, Kim HJ, Lee JH
Acta Crystallogr D Biol Crystallogr 70 1061-73 (2014)
Related entries: 4nu2, 4nuh

Cited: 30 times
EuropePMC logo PMID: 24699650

Abstract

Ice-binding proteins (IBPs) inhibit ice growth through direct interaction with ice crystals to permit the survival of polar organisms in extremely cold environments. FfIBP is an ice-binding protein encoded by the Antarctic bacterium Flavobacterium frigoris PS1. The X-ray crystal structure of FfIBP was determined to 2.1 Å resolution to gain insight into its ice-binding mechanism. The refined structure of FfIBP shows an intramolecular disulfide bond, and analytical ultracentrifugation and analytical size-exclusion chromatography show that it behaves as a monomer in solution. Sequence alignments and structural comparisons of IBPs allowed two groups of IBPs to be defined, depending on sequence differences between the α2 and α4 loop regions and the presence of the disulfide bond. Although FfIBP closely resembles Leucosporidium (recently re-classified as Glaciozyma) IBP (LeIBP) in its amino-acid sequence, the thermal hysteresis (TH) activity of FfIBP appears to be tenfold higher than that of LeIBP. A comparison of the FfIBP and LeIBP structures reveals that FfIBP has different ice-binding residues as well as a greater surface area in the ice-binding site. Notably, the ice-binding site of FfIBP is composed of a T-A/G-X-T/N motif, which is similar to the ice-binding residues of hyperactive antifreeze proteins. Thus, it is proposed that the difference in TH activity between FfIBP and LeIBP may arise from the amino-acid composition of the ice-binding site, which correlates with differences in affinity and surface complementarity to the ice crystal. In conclusion, this study provides a molecular basis for understanding the antifreeze mechanism of FfIBP and provides new insights into the reasons for the higher TH activity of FfIBP compared with LeIBP.

Articles - 4nu3 mentioned but not cited (2)

  1. Structure and application of antifreeze proteins from Antarctic bacteria. Muñoz PA, Márquez SL, González-Nilo FD, Márquez-Miranda V, Blamey JM. Microb Cell Fact 16 138 (2017)
  2. Multiple ice-binding proteins of probable prokaryotic origin in an Antarctic lake alga, Chlamydomonas sp. ICE-MDV (Chlorophyceae). Raymond JA, Morgan-Kiss R. J Phycol 53 848-854 (2017)


Reviews citing this publication (7)

  1. Marine Antifreeze Proteins: Structure, Function, and Application to Cryopreservation as a Potential Cryoprotectant. Kim HJ, Lee JH, Hur YB, Lee CW, Park SH, Koo BW. Mar Drugs 15 E27 (2017)
  2. Ice-binding proteins and the 'domain of unknown function' 3494 family. Vance TDR, Bayer-Giraldi M, Davies PL, Mangiagalli M. FEBS J 286 855-873 (2019)
  3. The Use of Antifreeze Proteins in the Cryopreservation of Gametes and Embryos. Robles V, Valcarce DG, Riesco MF. Biomolecules 9 E181 (2019)
  4. Ice Binding Proteins: Diverse Biological Roles and Applications in Different Types of Industry. Białkowska A, Majewska E, Olczak A, Twarda-Clapa A. Biomolecules 10 E274 (2020)
  5. Properties and biotechnological applications of ice-binding proteins in bacteria. Cid FP, Rilling JI, Graether SP, Bravo LA, Mora Mde L, Jorquera MA. FEMS Microbiol Lett 363 fnw099 (2016)
  6. Application of Nanoparticles and Melatonin for Cryopreservation of Gametes and Embryos. Choi HW, Jang H. Curr Issues Mol Biol 44 4028-4044 (2022)
  7. Antifreeze Proteins: A Tale of Evolution From Origin to Energy Applications. Gharib G, Saeidiharzand S, Sadaghiani AK, Koşar A. Front Bioeng Biotechnol 9 770588 (2021)

Articles citing this publication (21)

  1. Cryo-protective effect of an ice-binding protein derived from Antarctic bacteria. Mangiagalli M, Bar-Dolev M, Tedesco P, Natalello A, Kaleda A, Brocca S, de Pascale D, Pucciarelli S, Miceli C, Braslavsky I, Lotti M. FEBS J 284 163-177 (2017)
  2. The ice-binding proteins of a snow alga, Chloromonas brevispina: probable acquisition by horizontal gene transfer. Raymond JA. Extremophiles 18 987-994 (2014)
  3. An ice-binding and tandem beta-sandwich domain-containing protein in Shewanella frigidimarina is a potential new type of ice adhesin. Vance TDR, Graham LA, Davies PL. FEBS J 285 1511-1527 (2018)
  4. Dependence on epiphytic bacteria for freezing protection in an Antarctic moss, Bryum argenteum. Raymond JA. Environ Microbiol Rep 8 14-19 (2016)
  5. Structure and Properties of a Natural Competence-Associated Pilin Suggest a Unique Pilus Tip-Associated DNA Receptor. Salleh MZ, Karuppiah V, Snee M, Thistlethwaite A, Levy CW, Knight D, Derrick JP. mBio 10 e00614-19 (2019)
  6. Ice-binding proteins from the fungus Antarctomyces psychrotrophicus possibly originate from two different bacteria through horizontal gene transfer. Arai T, Fukami D, Hoshino T, Kondo H, Tsuda S. FEBS J 286 946-962 (2019)
  7. Diversity of Phototrophic Genes Suggests Multiple Bacteria May Be Able to Exploit Sunlight in Exposed Soils from the Sør Rondane Mountains, East Antarctica. Tahon G, Tytgat B, Willems A. Front Microbiol 7 2026 (2016)
  8. Draft genome sequences of bacteria isolated from the Deschampsia antarctica phyllosphere. Cid FP, Maruyama F, Murase K, Graether SP, Larama G, Bravo LA, Jorquera MA. Extremophiles 22 537-552 (2018)
  9. Structure of a bacterial ice binding protein with two faces of interaction with ice. Mangiagalli M, Sarusi G, Kaleda A, Bar Dolev M, Nardone V, Vena VF, Braslavsky I, Lotti M, Nardini M. FEBS J 285 1653-1666 (2018)
  10. Structural basis of antifreeze activity of a bacterial multi-domain antifreeze protein. Wang C, Pakhomova S, Newcomer ME, Christner BC, Luo BH. PLoS One 12 e0187169 (2017)
  11. Characterization of microbial antifreeze protein with intermediate activity suggests that a bound-water network is essential for hyperactivity. Khan NMU, Arai T, Tsuda S, Kondo H. Sci Rep 11 5971 (2021)
  12. Combined molecular dynamics and neural network method for predicting protein antifreeze activity. Kozuch DJ, Stillinger FH, Debenedetti PG. Proc Natl Acad Sci U S A 115 13252-13257 (2018)
  13. Growth suppression of ice crystal basal face in the presence of a moderate ice-binding protein does not confer hyperactivity. Bayer-Giraldi M, Sazaki G, Nagashima K, Kipfstuhl S, Vorontsov DA, Furukawa Y. Proc Natl Acad Sci U S A 115 7479-7484 (2018)
  14. Discovery of fibrillar adhesins across bacterial species. Monzon V, Lafita A, Bateman A. BMC Genomics 22 550 (2021)
  15. An Ice-Binding Protein from an Antarctic Ascomycete Is Fine-Tuned to Bind to Specific Water Molecules Located in the Ice Prism Planes. Yamauchi A, Arai T, Kondo H, Sasaki YC, Tsuda S. Biomolecules 10 E759 (2020)
  16. Effect of Marine-Derived Ice-Binding Proteins on the Cryopreservation of Marine Microalgae. Kim HJ, Koo BW, Kim D, Seo YS, Nam YK. Mar Drugs 15 (2017)
  17. Ice-Binding Proteins Associated with an Antarctic Cyanobacterium, Nostoc sp. HG1. Raymond JA, Janech MG, Mangiagalli M. Appl Environ Microbiol 87 e02499-20 (2021)
  18. Multiple binding modes of a moderate ice-binding protein from a polar microalga. Kondo H, Mochizuki K, Bayer-Giraldi M. Phys Chem Chem Phys 20 25295-25303 (2018)
  19. Prediction and analysis of antifreeze proteins. Miyata R, Moriwaki Y, Terada T, Shimizu K. Heliyon 7 e07953 (2021)
  20. Improving thermal hysteresis activity of antifreeze protein from recombinant Pichia pastoris by removal of N-glycosylation. Kim EJ, Lee JH, Lee SG, Han SJ. Prep Biochem Biotechnol 47 299-304 (2017)
  21. Protection of Alcohol Dehydrogenase against Freeze-Thaw Stress by Ice-Binding Proteins Is Proportional to Their Ice Recrystallization Inhibition Property. Lee YH, Kim K, Lee JH, Kim HJ. Mar Drugs 18 E638 (2020)


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